Electric vehicle

ABSTRACT

A power unit of an electric vehicle may be connected to a main battery, an AC inlet, and a DC inlet. The power unit may include a battery connector to which a battery power cable is connected, an AC inlet connector to which an AC inlet power cable is connected, and a DC inlet connector to which a DC inlet power cable is connected. The battery connector may be closer to the main battery than a center of the power unit is to the main battery. The AC inlet connector may be closer to the AC inlet than the center of the power unit is to the AC inlet. The DC inlet connector may be closer to the DC inlet than the center of the power unit is to the DC inlet.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority to Japanese Patent Application No.2018-243414, filed on Dec. 26, 2018, the entire contents of which areincorporated herein by reference.

TECHNICAL FIELD

The art disclosed herein relates to an electric vehicle.

BACKGROUND

An electric vehicle is provided with an electric power converterconfigured to convert electric power of a main battery to drive power ofa traction motor. An output voltage of the main battery exceeds 100volts, thus a voltage exceeding 100 volts is applied to the tractionmotor and the electric power converter. High voltage devices, such as anair conditioner, that are driven by the electric power of the mainbattery, are installed in the electric vehicle. Alternatively, an inletconfigured connectable to an external power supply for charging the mainbattery is connected to the main battery. The motor, the electric powerconverter, the inlet and the like are connected to the main battery bypower cables.

A power cable in the description herein includes a cable in whichelectric power from a main battery flows and a cable that transmitselectric power to the main battery. A device connected to the mainbattery by such a power cable is termed a high voltage device in thedescription herein.

A plurality of high voltage devices is connected to the main battery. Anelectric vehicle described in International Publication No. WO2014/030445 A1 is provided with a power distribution module (hereinbelowtermed “PDM”) for distributing electric power from a main battery to aplurality of high voltage devices. An inverter is mounted on a motorhousing that accommodates a traction motor, and the PDM is mounted onthe inverter (which is one type of high voltage devices). The PDMdistributes DC power of the main battery to the inverter. The inverterconverts the DC power of the main battery to drive power of the tractionmotor. The motor (motor housing) and the inverter are connected by apower cable, and the inverter and the PDM are also connected by anotherpower cable. The PDM and the main battery are also connected by yetanother power cable.

On the other hand, Japanese Patent Application Publication No.2012-85481 and Japanese Patent Application Publication No. 2014-239621describe electric vehicles that each include an inlet so as to allow amain battery to be charged by receiving electric power from a powersupply outside the vehicle. The inlet is connected to the main batteryby a power cable and a relay. The external power supply is connected tothe inlet. The electric power from the power supply is transmitted tothe main battery through the inlet and the power cable. Asaforementioned, the inlet is one type of high voltage devices. Theelectric vehicle of Japanese Patent Application Publication No.2014-239621 is provided with a DC inlet configured connectable with adirect current power supply (DC power supply) that supplies DC power andan AC inlet configured connectable with an alternating current powersupply (AC power supply) that supplies AC power.

SUMMARY

When a number of on-board high voltage devices, such as a main battery,an inverter (motor), and an inlet, becomes large, it is effective toprovide a power unit configured to relay electric power from one highvoltage device to another high voltage device, however, development ofsuch a power unit has just recently begun, and further improvements canbe made. The description herein provides an electric vehicle providedwith a power unit that is improved than a conventional power unit.

The electric vehicle of Japanese Patent Application Publication No.2014-239621 is capable of charging the main battery from either theexternal AC power supply or DC power supply. In this case, the powerunit must be provided with a connector to which a power cable of the ACinlet is connected, a connector to which a power cable of the DC inletis connected, and a connector to which a power cable of the main batteryis connected. The description herein provides an electric vehicle thatoptimizes an arrangement of connectors of a power unit and anarrangement of a main battery.

An electric vehicle disclosed in the description herein may comprise amain battery, a first inlet, a second inlet, and a power unit. A powersupply outside the vehicle may be connectable to the first inlet.Another power supply outside the vehicle may be connectable to thesecond inlet. The power unit may be connected to the main battery by abattery power cable, connected to the first inlet by a first inlet powercable, and connected to the second inlet by a second inlet power cable.The power unit may comprise a battery connector to which the batterypower cable is connected. The power unit further may comprise a firstinlet connector to which the first inlet power cable is connected and asecond inlet connector to which the second inlet power cable isconnected.

The battery connector may be closer to the main battery than a center ofthe power unit is to the main battery. The first inlet connector may becloser to the first inlet than the center of the power unit is to thefirst inlet. The second inlet connector may be closer to the secondinlet than the center of the power unit is to the second inlet.

According to the above arrangement, distances between the respectivedevices and their corresponding connectors can be shortened. That is,lengths of the power cables can be shortened. When the lengths of thepower cables are shortened, transmission loss of electric power can besuppressed.

Details and further improvements of the art disclosed herein will bedescribed in the following DETAILED DESCRIPTION.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a plan view of an electric vehicle of a first embodiment.

FIG. 2 is a side view of the electric vehicle of the first embodiment.

FIG. 3 is a front view of the electric vehicle of the first embodiment.

FIG. 4 is a front view of an electric vehicle of a second embodiment.

FIG. 5 is a plan view of an electric vehicle of a third embodiment.

FIG. 6 is a block diagram showing an internal structure of a power unit.

FIG. 7 is a plan view showing an arrangement of connectors of the powerunit.

FIG. 8 is a diagram showing a variant of a connection relationshipbetween a power unit and a main battery.

DETAILED DESCRIPTION First Embodiment

An electric vehicle 2 of an embodiment will be described with referenceto the drawings. FIG. 1 shows a plan view of the electric vehicle 2 ofthe first embodiment, FIG. 2 shows a side view of the electric vehicle2, and FIG. 3 shows a front view of the electric vehicle 2. In FIGS. 1to 3, a body 200, seats 97, 98, and tires are depicted with virtuallines to explain about a device layout in a front compartment 3. Fr in acoordinate system of FIGS. 1 to 3 indicates a vehicle front and Upindicates a vehicle top. L indicates a left lateral side of the vehicle.

The front compartment 3 has a motor housing 7 that accommodates atraction motor 70, an electric power converter 9, a power unit 100, acooler 91, an air conditioner 92, and an auxiliary battery 94 mountedtherein. Further, a DC/AC converter 93 is mounted in a cabin space. Abattery pack 30 is arranged under the cabin space. The front compartment3 and the cabin space are partitioned by a dashboard 19. In FIGS. 2 and3, depiction of the cooler 91, the air conditioner 92, the auxiliarybattery 94, and the DC/AC converter 93 is omitted.

The cooler 91 is configured to cool the motor 70 and the electric powerconverter 9 (to be described later). The air conditioner 92 isconfigured to adjust a temperature in the cabin space. The DC/ACconverter 93 is provided to enable usage of electric equipment in thecabin space. The cooler 91 and the air conditioner 92 are configured tooperate by electric power from a main battery 31.

The main battery 31 having an output voltage of 200 volts is provided inthe battery pack 30. In FIG. 3, depiction of the battery pack 30 is alsoomitted.

Aside from the motor 70, the motor housing 7 further accommodates agearset and a differential gear connected to an output shaft of themotor 70. Output torque of the motor 70 is transmitted to drive wheels(front wheels) through the gearset and the differential gear. The motorhousing 7 is bridged between a pair of side members 4 via vibrationabsorbers 8. In FIG. 1, a reference sign is not given to the uppervibration absorbers in the drawing. The motor housing 7 receives rotaryvibration of the motor 70 and vibration of the gearset, thus vibrates.The vibration absorbers 8 are configured to reduce vibration transmittedfrom the motor housing 7 to the side members 4.

The pair of side members 4 is a frame extending in a front-reardirection of the vehicle. Distal ends of the pair of side members 4 areconnected by a front cross member 6. The pair of side members 4 hastheir midpoints connected by two cross members 5. In other words, thetwo cross members 5 are bridged transversely over between the pair ofside members 4. The side members 4, the cross members 5, and the frontcross member 6 correspond to the frame that ensures strength of thevehicle. In FIG. 2, the side members 4 located rearward than thedashboard 19 are depicted with virtual lines.

The electric power converter 9 is fixed on the motor housing 7. Theelectric power converter 9 is configured to convert DC power of the mainbattery 31 to drive power of the motor 70. Since the motor 70 is athree-phase AC motor, the electric power converter 9 includes aninverter. By fixing the electric power converter 9 on the motor housing7, power cables between the electric power converter 9 and the motor 70become shorter, and transmission loss of three-phase alternating currentcan be suppressed. On the other hand, the electric power converter 9 isthereby vibrated with the motor housing 7.

The electric power of the main battery 31 is transmitted to the electricpower converter 9 through the power unit 100. The power unit 100 isfixed on the two cross members 5. The power unit 100 is connected to thebattery pack 30 (main battery 31) by two battery power cables (firstbattery power cable 23 and second battery power cable 24). The firstbattery power cable 23 is connected to a first battery connector 123provided at a rear portion (rear surface) of the power unit 100. Thesecond battery power cable 24 is connected to a second battery connector124 provided at the rear portion (rear surface) of the power unit 100. Areason why the power unit 100 and the battery pack 30 (main battery 31)are connected by these two power cables will be described later.

The power unit 100 is connected to the electric power converter 9 by aconverter power cable 25 (see FIG. 2). Depiction of the converter powercable 25 is omitted in FIGS. 1 and 3.

The motor housing 7 is supported by the side members 4 via the vibrationabsorbers 8, and the power unit 100 is fixed on the two cross members 5.In other words, the vibration absorbers 8 are interposed between thepower unit 100 and the motor housing 7. The power unit 100 and the motorhousing 7 are structurally connected via the vibration absorbers 8. Bysuch a structure, an influence of the vibration of the motor housing 7which the power unit 100 receives is reduced.

The power unit 100 not only relays the electric power of the mainbattery 31 to the electric power converter 9, but also relays theelectric power of the main battery 31 to the cooler 91 and also to theair conditioner 92. Further, the power unit 100 relays the electricpower of the main battery 31 to the auxiliary battery 94 and the DC/ACconverter 93 as well. An output voltage of the auxiliary battery 94 is12 volts, which is lower than the output voltage of the main battery 31(200 volts). The power unit 100 is provided with a step-down converter(to be described later), and the electric power of the main battery 31is stepped down and transmitted to the auxiliary battery 94.

The auxiliary battery 94 is charged by the electric power of the mainbattery 31. The auxiliary battery 94 is configured to supply electricpower to low voltage devices which the vehicle is provided with. Lowvoltage devices mean devices that operate by a voltage of the auxiliarybattery 94. Contrary to this, the main battery 31 and the devices towhich the electric power is transmitted from the main battery 31 arecollectively termed high voltage devices 90. The high voltage devicesinclude the main battery 31, the power unit 100, the electric powerconverter 9, the cooler 91, the air conditioner 92, and the DC/ACconverter 93. A DC inlet 11 and an AC inlet to be described later alsotransmit power with the main battery 31, thus belong to the high voltagedevices 90.

The DC/AC converter 93 steps down the voltage of the main battery 31 andthen converts the same to alternating current. Output alternatingcurrent of the DC/AC converter 93 conforms to a standard of commercialelectric power. That is, the DC/AC converter 93 is used for enablingusage of electric equipment inside the vehicle.

The DC inlet 11 and the AC inlet 12 are also connected to the power unit100. The DC inlet 11 is arranged at a front portion of a left sidesurface 201L of the electric vehicle 2 (near a left front fender). Inother words, the DC inlet 11 is arranged at a lateral forward portion ona front passenger seat 98 side. The DC inlet 11 is connected to thepower unit 100 by a DC inlet power cable 21. The DC inlet power cable 21is connected to a DC inlet connector 121 provided at a left frontportion (left side of a front surface) of the power unit 100. The DCinlet 11 is configured connectable to a connector of a DC power supplythat is outside the vehicle. Although details will be given later, theDC inlet power cable 21 is connected to the first battery power cable 23via the power unit 100. That is, the DC inlet 11 and the main battery 31are connected via the power unit 100. The main battery 31 is configuredcapable of being charged by electric power supplied from the external DCpower supply through the DC inlet 11. The DC power supply is a deviceconfigured to supply DC power.

The AC inlet 12 is arranged at a front portion of a right side surface201R of the electric vehicle 2 (near a right front fender). In otherwords, the AC inlet 12 is arranged at a lateral forward portion on adriver seat 97 side. The AC inlet 12 is connected to the power unit 100by an AC inlet power cable 22. The AC inlet power cable 22 is connectedto an AC inlet connector 122 provided at a right front portion (rightside of the front surface) of the power unit 100. The AC inlet powercable 22 is connected to the second battery power cable 24 via an AC/DCconverter (to be described later) provided in the power unit 100, thatis, the AC inlet 12 is connected to the main battery 31 via the AC/DCconverter.

The AC inlet 12 is configured connectable with an AC power supplyoutside the vehicle. The main battery 31 may be charged by electricpower supplied from the external AC power supply through the AC inlet 12and the AC/DC converter. The AC power supply is a device configured tosupply AC power. The AC/DC converter is a device configured to convertAC power to DC power.

A charging time of the main battery 31 becomes shorter with largercurrent of the electric power supplied from the external power supply.In order to flow large current, allowable current each of the DC inletpower cable 21 and of the first battery power cable 23 is 250 amperes ormore. Cross-sectional areas of the DC inlet power cable 21 and of thefirst battery power cable 23 are each 100 (mm²) or more to withstandcurrent of 250 amperes or more. When the cross-sectional area is 100(mm²) or more, flexibility of the power cable becomes quite low. Thepower cables with such low flexibility with the cross-sectional areas of100 (mm²) or more are connected to the power unit 100. When the powerunit 100 to which the power cables with the low flexibility areconnected is connected to the motor housing 7, the power cables vibrateaccompanying the vibration of the motor housing 7. There may be a fearthat, when the power cables with the low flexibility vibrate, highstress is generated at connectors (connectors of the power unit 100)connecting the power cables. Alternatively, a space must be securedaround the power cables with the low flexibility to tolerate thevibration thereof. As aforementioned, in the electric vehicle 2 of theembodiment, the influence of the vibration of the motor housing 7 isreduced by fixing the power unit 100 to the cross members 5.

In the converter power cable 25 connecting the power unit 100 and theelectric power converter 9, only the current that is less than 250amperes flows therein. Due to this, a cross-sectional area of theconverter power cable 25 is smaller than each of the cross-sectionalareas of the DC inlet power cable 21 and the first battery power cable23. That is, the converter power cable 25 has higher flexibility thanthe DC inlet power cable 21. The electric power converter 9 is fixed onthe motor housing 7, and vibrates together with the motor housing 7.Even if the electric power converter 9 vibrates, an influence of thevibration of the motor housing 7 imposed on the power unit 100 via theconverter power cable 25 is minor as compared to a case where a powercable with a large diameter is connected.

Second Embodiment

FIG. 4 shows a front view of an electric vehicle 2 a of a secondembodiment. In the electric vehicle 2 a of the second embodiment, aplate 5 a is bridged transversely over a left suspension tower 18L and aright suspension tower 18R, and the power unit 100 is fixed on the plate5 a. Other structures are same as those of the electric vehicle 2 of thefirst embodiment. That is, the power unit 100 is fixed to the body 200via the plate 5 a.

The left suspension tower 18L and the right suspension tower 18R areparts of the body 200 of the electric vehicle 2 a. Even by fixing thepower unit 100 to the body of the electric vehicle, the influence of thevibration which the power unit 100 receives from the motor housing 7 canbe suppressed.

The above configuration can also be expressed as follows. That is, thevibration absorbers 8 are interposed between the power unit 100 and themotor housing 7. Due to this, the influence of the vibration which thepower unit 100 receives from the motor housing 7 is reduced. The powerunit 100 may be fixed on a cross member bridged transversely over theleft suspension tower 18L and the right suspension tower 18R instead ofbeing fixed on the plate 5 a.

Third Embodiment

FIG. 5 shows a plan view of an electric vehicle 2 b of a thirdembodiment. In the electric vehicle 2 b of the third embodiment, the DCinlet 11 and the AC inlet 12 are provided at a front portion of the body200. Other structures are same as those of the electric vehicle 2 of thefirst embodiment. In the electric vehicle 2 b of the third embodiment,the battery pack 30 (main battery 31) is arranged rearward than thepower unit 100, and the first battery power cable 23 (and the secondbattery power cable 24) extending from the main battery 31 is connectedto the first battery connector 123 (and the second battery connector124) provided at the rear portion (rear surface) of the power unit 100.On the other hand, the DC inlet 11 is provided forward than the powerunit 100, and the DC inlet power cable 21 extending from the DC inlet 11is connected to the DC inlet connector 121 provided on the front portion(front surface) of the power unit 100. The AC inlet 12 is also providedforward than the power unit 100, and the AC inlet power cable 22extending from the AC inlet 12 is connected to the AC inlet connector122 provided on the front portion (front surface) of the power unit 100.

Arrangement of connectors including connectors for other high voltagedevices 90 will be described later again. (Power Unit) Next, a circuitryconfiguration of the power unit 100 that applies similarly to the firstto third embodiments will be described. FIG. 6 shows a block diagram ofan inside of the power unit. The power unit 100 has the main battery 31(battery pack 30), the DC inlet 11, the AC inlet 12, the electric powerconverter 9, the cooler 91, the air conditioner 92, the DC/AC converter93, and the auxiliary battery 94 connected thereto.

The power unit 100 and the main battery 31 are connected by two powercables (the first battery power cable 23 and the second battery powercable 24). The first battery power cable 23 is connected to the firstbattery connector 123 of the power unit 100. The second battery powercable 24 is connected to the second battery connector 124 of the powerunit 100.

Inside the battery pack 30, the first battery power cable 23 isconnected to the main battery 31 via a system main relay 32, and thesecond battery power cable 24 is connected to the main battery 31 via anAC charging relay 33. The system main relay 32 and the AC charging relay33 are controlled by a host controller that is not shown.

Inside the power unit 100, terminals of the first battery connector 123are connected to main power line 107. Various connectors are connectedto the main power line 107. A cooler connector 191, an air conditionerconnector 192, a DC/AC converter connector 193, and a converterconnector 125 are connected to the main power line 107. The main powerline 107 and the cooler 91 are connected via the cooler connector 191,the main power line 107 and the air conditioner 92 are connected via theair conditioner connector 192, and the DC/AC converter 93 and the mainpower line 107 are connected via the DC/AC converter connector 193.Further, the electric power converter 9 is connected to the main powerline 107 via the converter connector 125. Power cables that connect thehigh voltage devices 90 and their corresponding connectors, such aspower cable connecting the cooler 91 to the cooler connector 191 and apower cable connecting the air conditioner 92 to the air conditionerconnector 192, are collectively termed device power cables 99 in FIG. 6.For convenience of explanation, the AC inlet power cable 22 thatconnects the AC inlet 12 and the AC inlet connector 122 is excluded fromthe device power cables 99.

The main power line 107 has an auxiliary battery connector 127 connectedthereto via a step-down converter 104. A power cable extending from theauxiliary battery 94 is connected to the auxiliary battery connector127. The step-down converter 104 is configured to step down the voltageof the main battery 31 to the voltage of the auxiliary battery 94. Thatis, the auxiliary battery 94 is charged by the electric power of themain battery 31.

The main power line 107 is connected to the main battery 31 via thefirst battery connector 123, the first battery power cable 23, and thesystem main relay 32. Primary high voltage devices 90 mounted in thevehicle (including the electric power converter 9 and the step-downconverter 104) are connected to the main battery 31 via the main powerline 107, the first battery connector 123, the first battery power cable23, and the system main relay 32. In a case where the electric vehicle 2is provided with a rear motor 71 configured to drive rear wheels, a rearelectric power converter 136 configured to drive the rear motor 71 isconnected to the main power line 107 via a rear converter connector 126.The rear electric power converter 136 also belongs to the high voltagedevices 90.

The main power line 107 is a primary power line for relaying theelectric power of the main battery 31 to the vehicle-mounted highvoltage devices 90.

Aside from the step-down converter 104, the power unit 100 is providedwith a DC relay 103, a leak current detector 102, an AC/DC converter105, and a controller 106. The step-down converter 104, the DC relay103, the leak current detector 102, and the AC/DC converter 105 arecontrolled by the controller 106. In FIG. 6, broken lines in the powerunit 100 indicate signal lines. Solid lines in the power unit 100indicate power lines.

The DC inlet connector 121 is connected to the main power line 107 viathe DC relay 103 and the leak current detector 102. As aforementioned,one end of the DC inlet power cable 21 is connected to the DC inletconnector 121. The DC inlet 11 is connected to the other end of the DCinlet power cable 21. A connector 902 of a DC power supply 901 outsidethe vehicle can be connected to the DC inlet 11.

When the connector 902 of the DC power supply 901 is connected to the DCinlet 11, the controller 106 of the power unit 100 closes the DC relay103, by which the external DC power supply 901 and the main battery 31are connected. The system main relay 32 is closed by the host controllerthat is not shown. The main battery 31 is charged by electric powersupplied from the DC power supply 901. The DC power supply 901 is afacility configured capable of supplying DC power.

The electric vehicle 2 (2 a, 2 b) is capable of charging the mainbattery 31 by the large current exceeding 250 amperes. That is, theelectric vehicle 2 (2 a, 2 b) can charge the main battery 31 at fastspeed by receiving supply of the large current exceeding 250 amperesfrom the external DC power supply 901. Due to this, the DC inlet 11, theDC inlet power cable 21, the DC inlet connector 121, the main power line107, the first battery connector 123, the first battery power cable 23,and the system main relay 32 are designed to withstand the large currentexceeding 250 amperes. Especially, cables each having thecross-sectional area of 100 (mm²) or more are used as the DC inlet powercable 21 and the first battery power cable 23.

The power cables other than the DC inlet power cable 21 and the firstbattery power cable 23 each have the cross-sectional area that is lessthan 100 (mm²). The power cables other than the DC inlet power cable 21and the first battery power cable 23 may typically be 60 (mm²) or less.

On the other hand, the electric vehicle 2 (2 a, 2 b) is also capable ofcharging the main battery 31 by AC power of an external AC power supply903. The AC power supply 903 is a facility configured capable ofsupplying AC power.

A connector 904 of the AC power supply 903 is connected to the AC inlet12. The AC inlet power cable 22 extending from the AC inlet 12 isconnected to the AC inlet connector 122 of the power unit 100. The ACinlet connector 122 is connected to an AC input terminal of the AC/DCconverter 105 and a DC output terminal of the AC/DC converter 105 isconnected to the second battery connector 124. The AC/DC converter 105is configured to convert the AC power supplied from the external ACpower supply 903 to DC power, and further steps it up to the voltage ofthe main battery 31. Output current of the AC/DC converter 105 is 100amperes or less. Due to this, the cross-sectional area of the secondbattery power cable 24 is less than 100 (mm²). In other words, thecross-sectional area of the first battery power cable 23 is larger thanthe cross-sectional area of the second battery power cable 24. Further,the cross-sectional area of the DC inlet power cable 21 is larger thanthe cross-sectional area of the second battery power cable 24.

As shown in FIG. 6, the power unit 100 is connected to the main battery31 by the first battery power cable 23 and is connected to the mainbattery 31 by the second battery power cable 24 as well. The power unit100 and the main battery 31 have two power cables connected therebetweenin parallel. Further, the AC/DC converter 105 is connected to the secondbattery power cable 24 inside the power unit 100. The connectors forconnecting to the other high voltage devices 90 are connected to thefirst battery power cable 23. Examples of the other high voltage devices90 connected to the first battery power cable 23 are the electric powerconverter 9, the cooler 91, the air conditioner 92, the DC/AC converter93, the DC relay 103, and the like. Advantages of the aforementionedstructure will be described.

Firstly, even when a short circuit occurs in an AC charging system(which is a collective term for the AC inlet 12, the AC inlet powercable 22, the AC inlet connector 122, the AC/DC converter 105, and thesecond battery power cable 24), the electric vehicle 2 (2 a, 2 b) canstill travel. When the short circuit occurs in the AC charging system,the host controller that is not shown opens the AC charging relay 33 andcuts off the AC charging system from the main battery 31. The electricpower can still be supplied from the main battery 31 to the high voltagedevices 90 through the first battery power cable 23 even when the shortcircuit occurs in the AC charging system.

Secondly, by opening the system main relay 32 while charging the mainbattery 31 by receiving the electric power from the AC power supply 903through the AC inlet 12, other high voltage devices 90 can be cut offfrom the main battery 31. The plurality of high voltage devices 90includes devices which are not provided with a main switch and areconfigured to start up when the electric power is supplied thereto. Ifthe main battery 31 is charged with the electric power from the AC powersupply 903 while the system main relay 32 is closed, such high voltagedevices 90 not provided with the main switch may start up although theirstartup is not necessary. Such unnecessary startup of the high voltagedevices 90 brings forth wasteful electric power consumption anddeteriorates the high voltage devices 90 at a faster rate. By openingthe system main relay 32 during the charge by the AC power supply 903,an influence of the electric power obtained from the AC power supply 903can be suppressed from being imposed on the other high voltage devices90.

Thirdly, by connecting the power unit 100 and the battery pack 30accommodating the main battery 31 by two power cables, safety andspatial efficiency can both be achieved with excellent balancetherebetween. Firstly, during when a main switch of the vehicle is off,the high-voltage main battery 31 is preferably cut off from the otherhigh voltage devices, and in order to do so, it is preferable to providea relay (system main relay 32) in the battery pack 30.

Further, when the battery pack 30 and the power unit 100 are connectedby one power cable, the power line needs to be branched inside the powerunit 100 into a high voltage device system and the AC charging system,and separate relays need to be provided for the respective systems. Inthis case, one relay is provided in the battery pack 30 and two relaysare provided in the power unit 100. As such, three relays becomenecessary when the battery pack 30 and the power unit 100 are connectedby one power cable. Especially large current may flow in the cable thatelectrically connects with the external DC power supply 901, thus arelay size accordingly becomes larger. That is, a large-sized relaybecomes necessary for each of the battery pack 30 and the power unit100. As aforementioned, current exceeding 250 amperes does not flow inthe AC charging system. Due to this, the power cable dedicated to ACcharging (second battery power cable 24) may have a smaller diameterthan the power cable (first battery power cable 23) used in DC charging,and a size of the relay used for the AC charging may be smaller than asize of the relay used for the DC charging. The electric vehicle 2 ofthe embodiment connects the battery pack 30 and the power unit 100 bytwo power cables, however, a size of the power unit 100 can be madecompact since it simply needs to be provided with the system main relay32 having a large size for the DC charging and the AC charging relay 33having a small size for the AC charging. By accommodating the ACcharging relay 33 in the battery pack 30 as well, all the high voltagedevices 90 can be cut off from the battery pack 30 while the main switchof the vehicle is off. That is, by connecting the battery pack 30 andthe power unit 100 by two power cables, both the safety and the spatialefficiency can be achieved.

The arrangements of the connectors which the power unit 100 has will bedescribed in detail. FIG. 7 shows a plan view of the front compartment3. FIG. 7 shows a relationship of the power unit 100 and the connectorsthereof, the battery pack 30 (main battery 31), the DC inlet 11, and theAC inlet 12, and some of components that were depicted in the plan viewof FIG. 1 are omitted. Further, the body 200 is depicted in a virtualline in FIG. 7 as well. In FIG. 7, the power unit 100 is fixed to twoside members 4.

The DC inlet 11 is arranged on the left side surface 201L of the body200, and the AC inlet 12 is arranged on the right side surface 201R.More specifically, the DC inlet 11 is arranged near the left frontfender 202L and the AC inlet 12 is arranged near the right front fender202R. The DC inlet connector 121 is arranged on the left front side ofthe power unit 100 and the AC inlet connector 122 is arranged on theright front side of the power unit 100. The DC inlet 11 and the DC inletconnector 121 are connected by the large-diameter DC inlet power cable21 having the cross-sectional area of 100 (mm²) or more. The AC inlet 12and the AC inlet connector 122 are connected by the AC inlet power cable22 having the cross-sectional area smaller than that of the DC inletpower cable 21.

The DC inlet 11 and the DC inlet connector 121 are arranged leftwardfrom a center CP of the power unit 100 and the AC inlet 12 and the ACinlet connector 122 are arranged rightward from the center CP of thepower unit 100.

The AC inlet connector 122 is arranged closer to the AC inlet 12 thanthe center CP of the power unit 100 is to the AC inlet 12. The DC inletconnector 121 is arranged closer to the DC inlet 11 than the center CPof the power unit 100 is to the DC inlet 11.

The main battery 31 is arranged at a vehicle rear side from the powerunit 100. The first battery connector 123 is arranged on the rearsurface of the power unit 100 and the second battery connector 124 isarranged at the rear portion (right rear portion) of the power unit 100.In other words, the battery connectors 123, 124 are arranged closer tothe main battery 31 than the center CP of the power unit 100 is to themain battery 31.

According to the above arrangement, the power cables (DC inlet powercable 21 and AC inlet power cable 22) between the inlets and the powerunit can be made short, and the battery power cables 23, 24 can also bemade short.

The converter connector 125 and the rear converter connector 126 areprovided on the rear surface of the power unit 100. The auxiliarybattery connector 127 is provided on a front side of a right sidesurface of the power unit 100. The cooler connector 191, the airconditioner connector 192, and the DC/AC converter connector 193 areprovided on the right side surface of the power unit 100.

A variant of the connection relationship of the power unit 100 and thebattery pack 30 (main battery 31) will be described using FIG. 8. InFIG. 8, only devices related to the second battery power cable 24 aredepicted. Other devices are same as those in the block diagram of FIG.6.

In the variant, a noncontact electric power transmitter 131 is providedat a point on the second battery power cable 24. By providing thenoncontact electric power transmitter 131, the main battery 31 can becharged while electrically insulating the external AC power supply 903and the main battery 31. The noncontact electric power transmitter 131may typically be an electric power transmitter that uses a transducer.

A solar cell panel 132 is connected to the second battery power cable24. The main battery 31 may also be charged by the solar cell panel 132.

Some of primary features of the embodiments will be listed. Thetechnical elements described below are each independent technicalelements that achieve technical usefulness alone or in variouscombinations, and are not limited to the combination recited in theclaims as originally filed.

(1) The power unit 100 is connected to the main battery 31 by thebattery power cables (first battery power cable 23 and second batterypower cable 24). The power unit 100 is connected to the DC inlet 11(ACinlet 12) by the DC inlet power cable 21 (AC inlet power cable 22). Thepower unit 100 is connected to the electric power converter 9 by theconverter power cable 25. The power unit 100 is configured capable oftransmitting the electric power supplied through the inlets 11, 12 tothe main battery 31, and of transmitting the electric power of the mainbattery 31 to the electric power converter 9. The power unit 100 isfixed to the body 200 or the frame (side members 4 or cross members 5)of the vehicle.

(2) The motor housing 7 accommodating the motor 70 is supported on theframe (side members 4 or cross members 5) via the vibration absorbers 8.The electric power converter 9 is fixed on the motor housing 7. Theelectric power converter 9 vibrates together with the motor housing 7.On the other hand, the power unit 100 has the vibration absorbers 8interposed between itself and the motor housing 7, and the influence ofthe vibration of the motor housing 7 which the power unit 100 receivesis suppressed.

(3) The cross-sectional area of each of the first battery power cable 23and the DC inlet power cable 21 is larger than the cross-sectional areaof the converter power cable 25. The power unit 100 is connected withthe electric power converter 9, which vibrates together with the motorhousing 7, by the converter power cable 25 having the smallcross-sectional area. The influence of the vibration transmitted to thepower unit 100 through the converter power cable 25 is minor. On theother hand, the vibration of the motor housing 7 transmitted to thefirst battery power cable 23 and the DC inlet power cable 21 having thelarge cross-sectional areas is reduced by the vibration absorbers 8.

(4) The main battery 31 is arranged at the vehicle rear side from thepower unit 100. The first battery power cable 23 and the second batterypower cable 24 are connected to the rear portion of the power unit 100.Since the battery power cables are connected to the side of the powerunit 100 that is closer to the main battery 31, the battery power cablescan be made short.

(5) The DC inlet 11 and the AC inlet 12 are provided at the frontportion of the vehicle. The DC inlet power cable 21 and the AC inletpower cable 22 are connected to the front portion of the power unit 100.By this structure, the DC inlet power cable 21 and the AC inlet powercable 22 can be made short.

(6) The DC inlet 11 is provided on a lateral side (left lateral side) ofthe vehicle and the DC inlet power cable 21 is connected to a portion ofthe power unit 100 that is on a same side as the DC inlet 11 withrespect to the center CP of the power unit 100. The AC inlet 12 isprovided on a lateral side (right lateral side) of the vehicle and theAC inlet power cable 22 is connected to a portion of the power unit 100that is on a same side as the AC inlet 12 with respect to the center CPof the power unit 100.

(7) The AC inlet power cable 22 is connected to the second battery powercable 24 via the AC/DC converter 105 inside the power unit 100. Thefirst battery power cable 23 is connected to the power cables 99 of thehigh voltage devices 90 other than the AC/DC converter 105. Theinfluence of the external AC power supply 903 imposed on the highvoltage devices 90 other than the AC/DC converter 105 can be reduced.

(8) The power unit 100 is connected to the DC inlet 11 by the DC inletpower cable 21. The DC inlet power cable 21 is connected to the firstbattery power cable 23 via the DC relay 103 and the main power line 107inside the power unit 100.

(9) A first relay is provided between the first battery power cable 23and the main battery 31. Further, a second relay is provided between thesecond battery power cable 24 and the main battery 31. The other highvoltage devices 90 (such as the electric power converter 9, the cooler91, the air conditioner 92, and the DC/AC converter 93) can be cut offfrom the main battery 31 when the main battery 31 is charged by theelectric power of the AC power supply 903. On the other hand, duringwhen the charging by the AC power supply 903 is not executed, the AC/DCconverter 105 and the AC inlet 12 can be cut off from the main battery31. The first relay corresponds to the system main relay 32 and thesecond relay corresponds to the AC charging relay 33.

(10) The electric vehicle 2 (2 a, 2 b) is provided with a first inletand a second inlet. The AC power supply outside the vehicle isconnectable to one of the inlets. The DC power supply outside thevehicle is connectable to the other of the inlets. The power unit 100 isconnected to the first inlet by a first inlet power cable and to thesecond inlet by a second inlet power cable. The power unit is providedwith the first battery connector 123, the second battery connector 124,a first inlet connector, and a second inlet connector. The first batterypower cable 23 extending from the main battery 31 is connected to thefirst battery connector 123. The second battery power cable 24 extendingfrom the main battery 31 is connected to the second battery connector124.

(11) The first inlet power cable extending from the first inlet isconnected to the first inlet connector. The second inlet power cableextending from the second inlet is connected to the second inletconnector. The battery connectors 123, 124 are arranged closer to themain battery 31 than the center CP of the power unit 100 is to the mainbattery 31. The first inlet connector is arranged closer to the firstinlet than the center CP of the power unit 100 is to the first inlet.The second inlet connector is arranged closer to the second inlet thanthe center CP of the power unit 100 is to the second inlet.

(12) The main battery 31 is arranged at the vehicle rear side from thepower unit 100. The battery connectors 123, 124 are provided at the rearportion of the power unit 100.

(13) The first inlet is provided on a first lateral surface of theelectric vehicle 2 and the second inlet is provided on a second lateralsurface opposite to the first lateral surface of the electric vehicle 2.The first inlet connector is provided on a first lateral surface sidefrom the center CP of the power unit and the second inlet connector isprovided on a second lateral surface side from the center CP of thepower unit.

The AC inlet 12 corresponds to the first inlet and the DC inlet 11corresponds to the second inlet. The AC inlet power cable 22 correspondsto the first inlet power cable and the DC inlet power cable 21corresponds to the second inlet power cable. The AC inlet connector 122corresponds to the first inlet connector and the DC inlet connector 121corresponds to the second inlet connector. The DC inlet 11 is providedon the front side of the left lateral surface of the vehicle and the ACinlet 12 is provided on the front side of the right lateral surface ofthe vehicle.

Other features of the art described in the embodiments will bedescribed. Some of the connectors which the power unit 100 is providedwith may have a fuse assembled therein.

The “electric vehicle” in the description herein includes a hybridvehicle provided with both a motor and an engine and a vehicle thatmounts a fuel cell together with a battery.

Specific examples of the present invention have been described indetail, however, these are mere exemplary indications and thus do notlimit the scope of the claims. The art recited in the claims includesmodifications and variations of the specific examples presented above.Technical features described in the description and the drawings maytechnically be useful alone or in various combinations, and are notlimited to the combinations as originally claimed. Further, the artdescribed in the description and the drawings may concurrently achieve aplurality of aims, and technical significance thereof resides inachieving any one of such aims.

What is claimed is:
 1. An electric vehicle comprising: a main battery; afirst inlet connectable with a power supply outside the vehicle; asecond inlet connectable with another power supply outside the vehicle;and a power unit connected to the main battery by a battery power cable,connected to the first inlet by a first inlet power cable, and connectedto the second inlet by a second inlet power cable; wherein the powerunit comprises: a battery connector to which the battery power cable isconnected; a first inlet connector to which the first inlet power cableis connected; and a second inlet connector to which the second inletpower cable is connected, the battery connector is closer to the mainbattery than a center of the power unit is to the main battery, thefirst inlet connector is closer to the first inlet than the center ofthe power unit is to the first inlet, and the second inlet connector iscloser to the second inlet than the center of the power unit is to thesecond inlet.
 2. The electric vehicle according to claim 1, wherein themain battery is arranged on a rear side in the vehicle from the powerunit, and the battery connector is arranged at a rear portion of thepower unit.
 3. The electric vehicle according to claim 1, wherein thefirst inlet is arranged on a first lateral surface of the electricvehicle, the second inlet is arranged on a second lateral surfaceopposite to the first lateral surface of the electric vehicle, the firstinlet connector is closer to the first lateral surface than the centerof the power unit in a vehicle width direction is to the first lateralsurface, and the second inlet connector is closer to the second lateralsurface than the center of the power unit in the vehicle width directionto the second lateral surface.
 4. The electric vehicle according toclaim 1, wherein the first inlet is an AC inlet connectable with an ACpower supply configured to output AC power, and the AC inlet is arrangedon a right side of the vehicle, and the second inlet is a DC inletconnectable with a DC power supply configured to output DC power, andthe DC inlet is arranged on a left side of the vehicle.